Tool for creating customized user interface definitions for a generic utility supporting on-demand creation of field device editor graphical user interfaces

ABSTRACT

A customization tool is described in association with a universal device type manager (DTM) utility. The customization tool includes a set of user interfaces and associated functionality that facilitates creating a set of customized templates for a particular device type. The customized templates define access to device data via graphical user interfaces supported by the universal DTM utility and/or universal BTM utility for instances of the device type.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the priority benefit of Bump et al., U.S. patent application Ser. No. 11/244,860, filed on Oct. 5, 2005, entitled “GENERIC UTILITY SUPPORTING ON-DEMAND CREATION OF CUSTOMIZABLE GRAPHICAL USER INTERFACES FOR VIEWING AND SPECIFYING FIELD DEVICE PARAMETERS,” the contents of which are expressly incorporated herein by reference in their entirety, including any references therein.

This application relates to Bump et al., U.S. patent application Ser. No. 11/403,228, filed on Apr. 11, 2006, entitled “UTILITY FOR COMPARING DEPLOYED AND ARCHIVED PARAMETER VALUE SETS WITHIN A FIELD DEVICE EDITOR” the contents of which are expressly incorporated herein by reference in their entirety, including any references therein.

This application relates to Bump et al. U.S. patent application Ser. No. 11/403,224, filed on Apr. 11, 2006, entitled “METHOD AND SUPPORTING CONFIGURATION USER INTERFACES FOR STREAMLINING INSTALLING REPLACEMENT OF FIELD DEVICES,” the contents of which are expressly incorporated herein by reference in their entirety, including any references therein.

FIELD OF THE INVENTION

This invention relates generally to networked computerized industrial process control systems and, more particularly, relates to utilities providing lifetime support of field devices such as transmitters, positioners, etc. Tasks associated with such lifetime support include configuring, commissioning, monitoring, maintaining and replacing the field devices within an industrial process control system environment including potentially many types of field device types.

BACKGROUND

Industry increasingly depends upon highly automated data acquisition and control systems to ensure that industrial processes are run efficiently, safely and reliably while lowering their overall production costs. Data acquisition begins when a number of sensors measure aspects of an industrial process and periodically report their measurements back to a data collection and control system. Such measurements come in a wide variety of forms and are used by industrial process control systems to regulate a variety of operations, both with respect to continuous and discrete manufacturing processes. By way of example the measurements produced by a sensor/recorder include: a temperature, a pressure, a pH, a mass/volume flow of material, a quantity of bottles filled per hour, a tallied inventory of packages waiting in a shipping line, or a photograph of a room in a factory. Often sophisticated process management and control software examines the incoming data, produces status reports, and, in many cases, responds by sending commands to actuators/controllers that adjust the operation of at least a portion of the industrial process. The data produced by the sensors also allow an operator to perform a number of supervisory tasks including: tailor the process (e.g., specify new set points) in response to varying external conditions (including costs of raw materials), detect an inefficient/non-optimal operating condition and/or impending equipment failure, and take remedial actions such as adjust a valve position, or even move equipment into and out of service as required.

Typical industrial processes today are extremely complex and comprise many intelligent devices such as transmitters, positioners, motor drives, limit switches and other communication enabled devices. By way of example, it is not unheard of to have thousands of sensors and control elements (e.g., valve actuators) monitoring/controlling aspects of a multi-stage process within an industrial plant. As field devices have become more advanced over time, the process of setting up field devices for use in particular installations has also increased in complexity.

In previous generations of industrial process control equipment, and more particularly field devices, transmitters and positioners were comparatively simple components. Before the introduction of digital (intelligent) transmitters, setup activities associated with a field device were relatively simple. Industry standards like 3-15 psi for pneumatic instruments or 4-20 ma for electronic instruments allowed a degree of interoperability that minimized setup and configuration of analog transmitters.

More contemporary field devices that include digital data transmitting capabilities and on-device digital processors, referred to generally as “intelligent” field devices, require significantly more configuration effort when setting up a new field device. During configuration a set of parameters are set, within the new device, at either a device level (HART, PROFIBUS, FoxCOM, DeviceNet) or a block level within the device (FOUNDATION™ fieldbus).

Lifetime management of complex, intelligent devices requires any user performing any one of a variety of lifetime activities to possess considerable knowledge of the specific device that is being managed. In view of this need, a field device tool (FDT) standard was created that defines a set of interfaces for providing device-specific field device management user interfaces for a variety of devices via a set of device-specific add-on components.

A known FDT architecture comprises a frame application, device DTMs, and DTMs for communications devices (Comm DTMs). The FDT frame application implements FDT-compliant interfaces for DTMs to enable management of a variety of field device types, operating under a variety of protocols. The frame application (Platform) and DTMs, when combined, provide a set of graphical user interfaces (GUIs) that abstract specific implementation details of particular systems and devices thereby rendering differences between their associated protocols transparent to higher level applications built on top of the FDT architecture. Examples of such abstracted implementation details include: physical interfaces connecting to devices, persistent data storage, system management, and locations and types for device parameters.

In addition to the frame application, the FDT architecture, by way of example, also includes a communication device type manager (Comm DTM), and device DTM. A Comm DTM performs the parameterization of communication devices such as Profibus-interface boards, Hart Modems or Gateways from Ethernet to Profibus. The Comm DTMs define a standard communications interface (e.g., Set, Get, etc.) for accessing data within online devices (e.g., Fieldbus devices) using a particular communications protocol.

Device DTMs, in general, are the drivers for lifetime management of field devices. Known device-specific DTMs encapsulate the device-specific data and functions such as the device structure, its communication capabilities, and internal dependencies. Device DTMs can also specify a graphic interface for presenting, for example, a configuration interface for an associated field device. The device DTMs provide a standardized set of interfaces to device data within field devices. Device DTMs provide/support, for example, visualization of a device status, analysis, calibration, diagnostics, and data access with regard to devices with which the device DTMs are associated. Device DTMs plug into the Frame Application and become the high-level interface for the devices. Device DTMs communicate with their associated devices through standardized interface methods supported by Comm DTMs.

The following is a general example of a setup embodying the FDT architecture. A field device is mounted to a fieldbus. However, the device is not ranged out in the field. Instead, the operator, via a workstation, installs device DTM software on a computer executing the frame application that serves as the host of the DTM. Next, the Comm DTM for communicating with the field device is installed on the computer system having the DTM and frame application. The channel associated with the Comm DTM supports communications to/from the fieldbus. A pointer to the main interface, the channel is passed to the device DTM. At this point the device DTM is able to speak to the field device through the channel according to the protocol specified by the channel using specified FDT interfaces.

In the above-described example, the device DTM is pre-defined for a particular device type. As such, the DTM cannot be used for other types of devices. Furthermore, providing specific DTMs for particular device types leads to a variety of vendor and device type-specific user interfaces. A known DTM development environment developed by CodeWrights GmbH implements a tool which allows a developer to create device-specific DTMs using HART Communication Foundation Device Description (DD) files as a starting point. However, the known DTM development tool requires expert programming knowledge to fully resolve and create the user interface. In the known DTM development environment DTMs cannot be created without a user first providing programming input.

Intelligent field devices today are becoming increasingly sophisticated. Such devices support a variety of configurable and observable parameters via DTMs and, in the case of field devices having associated blocks (e.g., transducer, analog in, etc.), block type managers (BTMs). The DTMs and BTMs are used by a wide variety of users to perform particular role-related tasks. For example, an operator who merely monitors/supervises devices in a runtime environment is unlikely to need access to the same set of device parameters as a process engineer who performs a variety of commissioning and maintenance tasks on such devices. The DTMs and BTMs will be generally referred to herein as “type managers” (TMs).

Still yet another challenge when viewing a sophisticated device or block is gaining an understanding of what modifications have been made to the configurable parameters associated with the device. Making such determination on a single device can be an ordeal. The task is compounded when it must be performed on hundreds of devices or blocks.

SUMMARY OF THE INVENTION

In view of the challenges and complexities of maintaining field devices of potentially many types, including transmitters, positioners, motor drives, motor control centers, light curtains, limit switches and other communication enabled devices from a variety of vendors, and the varying needs of users who access information associated with such devices during the course of executing particular role-specific tasks, a customization tool is provided in association with a universal device type manager (DTM) utility. The customization tool facilitates creating a set of customized, application-specific templates for a device type. The customized templates define access to device data via graphical user interfaces supported by the universal DTM utility and/or universal BTM utility for instances of the device type. The universal DTM and BTM utilities are generally referred to herein as universal type managers (TMs).

In accordance with the present invention, customization tool is provided in a device configuration environment for creating customized definitions for user interfaces supported by a field device editor. The customization tool includes an editor definition selection control for specifying a first device template corresponding to a device type stored in a device definition database. The first device template includes a first definition of an editor interface for the device type. An editor graphical user interface, comprising a set of user-selectable screens enables a user to modify the first definition of the editor interface via a customization tool provided via the editor interface for the device type, thereby rendering a modified version of the first definition of the editor interface. The customization tool furthermore includes an editor store control for storing the modified version of the editor definition.

BRIEF DESCRIPTION OF THE DRAWINGS

While the appended claims set forth the features of the present invention with particularity, the invention, together with its objects and advantages, may be best understood from the following detailed description taken in conjunction with the accompanying drawings of which:

FIG. 1 is schematic diagram depicting an exemplary process control network environment wherein the present invention is potentially incorporated;

FIG. 2 schematically depicts a set of entities, and their corresponding interfaces, associated with an exemplary universal FDM embodying the present invention;

FIG. 3 is a flowchart summarizing the on-demand creation of a customized universal DTM for presenting a set of GUIs associated with lifetime management of any device for which a standard device description (DD) is provided;

FIG. 4 is an illustrative graphical user interface associated with launching a DTM from a host application;

FIG. 5 is an illustrative graphical user interface associated with a device home page rendered by a universal device type manager;

FIG. 6 is an illustrative graphical user interface associated with a system management screen accessed via a tab presented on the device home page;

FIG. 7 is an illustrative graphical user interface associated with a network management screen accessed via a tab presented on the device home page;

FIG. 8 is an illustrative graphical user interface associated with a diagnostics screen accessed via a tab presented on the device home page;

FIG. 9 is an illustrative graphical user interface associated with a security screen accessed via a tab presented on the device home page;

FIG. 10 is an illustrative graphical user interface associated with a block home page rendered by a universal block type manager;

FIG. 11 is an illustrative graphical user interface associated with a configuration screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 12 is an illustrative graphical user interface associated with a tuning screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 13 is an illustrative graphical user interface associated with a watch screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 14 is an illustrative graphical user interface associated with a diagnostics screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 15 is an illustrative graphical user interface associated with a methods screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 16 is an illustrative graphical user interface associated with a security screen accessed via a tab presented on the universal block type manager interfaces;

FIG. 17 is an illustrative graphical user interface associated with a customization utility accessed via a “Customization” tab presented on the universal block type manager interfaces;

FIG. 18 an illustrative graphical user interface associated with a screen accessed via a Group Parameters button in the Customization view;

FIG. 19 an illustrative graphical user interface associated with a screen accessed via a Group Overview button in the Customization view;

FIG. 20 an illustrative graphical user interface associated with a screen accessed via a Define Tabs button in the Customization view;

FIG. 21 an illustrative graphical user interface associated with a screen accessed via a Details . . . button under a “Process” tab name in the Define Tabs view;

FIG. 22 an illustrative graphical user interface associated with a screen accessed via a Tab Overview button in the Customization view;

FIG. 23 an illustrative graphical user interface associated with a screen accessed via a Set Permissions button in the Customization view;

FIG. 24 an illustrative graphical user interface associated with a screen accessed via a Setup Downloads button in the Customization view;

FIG. 25 summarizes a set of steps associated with defining and storing a customized child editor template for a device/block;

FIG. 26 summarizes a set of steps for invoking a particular configuration of a customized child editor based upon a requestor's role(s); and

FIG. 27 is an exemplary user interface for supporting a compare function within an editor facility.

DETAILED DESCRIPTION OF THE DRAWINGS

In accordance with the general FDT architecture described above, device DTMs are hosted by the frame application which provides a basic user interface framework within which the individual device DTMs provide their own specialized interfaces. The frame application includes a hierarchical directory tree arrangement that shows various selectable/configurable system resources. The frame application accesses the DTMs through interfaces to manage the DTMs. The DTMs access the frame through another set of interfaces that allow the DTM to acquire information from, and transmit data to, the frame application.

In summary of exemplary embodiments of the present invention described herein, lifetime management of a variety of field devices having differing device descriptions is supported by a single universal device type manager (DTM) utility. The universal DTM functionality renders on-demand, in association with an FDT frame application, a variety of device type-specific DTM user interfaces. In the illustrative embodiment, the universal DTM supplements device type-specific DTMs provided for specific field devices and enables customizable lifetime management user interfaces for field devices for which suitable DTMs are not available.

Turning to FIG. 1, an exemplary simple industrial process control system arrangement/environment is depicted. A workstation 102, comprising a variety of field device configuration and monitoring applications, provides an operator/engineering interface through which an engineer/technician monitors the components of an industrial process control system. The workstation 102 comprises any of a variety of hardware/operating system platforms. By way of example, the workstation 102 comprises a personal computer running on MICROSOFT's WINDOWS operating system. However, alternative embodiments of the invention can potentially run on any one or more of a variety of operating systems such as: Unix, Linux, Solaris, Mac OS-X, etc.

In accordance with an embodiment of the present invention, the workstation 102 hosts a frame application, a universal DTM, one or more Comm DTMs, and a set of device type-specific DTMs. The frame application, for example INVENSYS's IACC frame application, provides access to a database for persistent storage of device descriptions (device definition database 107) as well as an application database 109 that stores a set of DTM customization definitions for defining particular field device access via the universal FF DTM embodying the present invention.

As explained above, DTMs operate within an FDT frame application on the workstation 102. The frame application provides the specified FDT interfaces defined in the FDT specification. The FDT frame application comprises client applications that use DTMs, databases 107 and 109 for persistent storage of device descriptions/DTM parameters, and a communication link to the field devices. FDT frame applications are incorporated into engineering tools for control systems (e.g., INVENSYS's IACC) as well as standalone tools for device configuration. One or more Comm DTMs facilitate communications between the universal DTM and field devices.

In the illustrative example, the workstation 102, device definition database 107 and application database 109 are connected in a redundant configuration via dual Ethernet interfaces/wiring to redundant switches 104 and 106. The Ethernet switches 104 and 106 are commercially available and provided, for example, by Allied Telesyn (e.g., model AT-8088/MT). While not specifically depicted in FIG. 1, additional nodes, comprising workstations, servers and other elements (e.g., control module assemblies) of a supervisory portion of the process control system are potentially connected to the redundant switches 104 and 106. In the illustrated embodiment, a device definition database 107 and application database 109 store information regarding device types (templates) and device instances, respectively. Furthermore, while hardwired connections between the workstation and switches 104 and 106 via ETHERNET local area network links are depicted in FIG. 1, such links over a local supervisory level process control network are alternatively carried out via wireless network interfaces.

The switches 104 and 106 (as well as potentially other non-depicted switches) are also communicatively coupled to a control module assembly 108. The control module assembly 108 comprises one or more control modules (also referred to as control processors). An illustrative example of such control module assembly 108 is a Foxboro CP model FCP270, by Invensys Systems, Inc. In other embodiments, process control functionality is carries out in any of a variety of control modules—even by control programs incorporated into the workstations, intelligent transmitters, or virtually any communicatively coupled device capable of executing control programs, loops, scripts, etc.

With continued reference to FIG. 1, an I/O module assembly 110, alternatively referred to as a field bus module, is connected to the control module assembly 108. The communications protocols utilized for carrying out communications between the I/O module assembly 110 and control module assembly 108 is potentially any one of a variety of proprietary/non-proprietary communications protocols. In one embodiment, the communications between the control module assembly 108 and I/O module assembly 110 are carried out via a 2 MBit HDLC communication bus. While only a single I/O module assembly 110 is depicted in the illustrative example, embodiments of the invention comprise many I/O module assemblies.

The I/O module assemblies, in general, include a variety of interfaces for communicating directly and/or indirectly to a variety of devices including, for example, field devices. In the illustrative example, the I/O module assembly 110 comprises a Foundation Fieldbus I/O module (e.g., an INVENSYS's field bus module model FBM228) that supports communications between the control module assembly 108 and a Foundation Fieldbus network 111. In the illustrative embodiment, a set of representative intelligent field devices 114 and 116, containing multiple application-dependent configurable parameters, are connected to the Foundation Fieldbus network 111. The field devices 114 and 116 operate at the lowest level of an industrial process control system to measure (transmitters) and control (positioners) plant activity. A Termination Assembly 112 communicatively couples the I/O module assembly 110 to the field devices 114 and 116. The termination assembly 112 provides power and power conditioning to the extent needed by the field devices 114 and 116 on the network 111.

The process control network schematically depicted in FIG. 1 is greatly simplified for purposes of illustration. Those skilled in the art will readily appreciate that both the number of components, at each depicted level of the exemplary process control system, is generally many times greater than the number of depicted components. This is especially the case with regard to the number of depicted field devices. In an actual process control environment, the number of field devices, comprising both input devices (e.g., transmitters) and output devices (e.g., positioners) number in the hundreds for an industrial process control system. Incorporation of a field device configuration infrastructure/toolset that supports archiving configurable parameter value sets for each field device presently within a process control system, and thereafter downloading such parameter values into replacement field devices (of the same type and therefore having the same configurable parameter value sets as field devices that are to be replaced) at the time of replacement, facilitates streamlining the field device replacement task. Such infrastructure and replacement method are described further herein below.

Turning to FIG. 2, a schematic diagram illustratively depicts primary components of an FDT application environment including a universal DTM 200 embodying the present invention. In the exemplary embodiment, the universal DTM 200 is implemented as a component object model (COM) object that complies with FDT specification 1.2, or higher, as further defined for FF. The universal DTM 200 comprises multiple sub-components that provide support for providing device type-specific DTM user interfaces according to a generic/default specification associated with the universal DTM 200. The primary program components of a universal DTM 200 are a business object 204 and one or more presentation objects 206.

An engineering database 202 includes device data 205, screen customization descriptions 207, and a default device template 209 (from which customized universal DTM templates are derived) comprise portions of an engineering database 202. A default device template 209 specifies the base functionality/appearance of the universal DTM 200, including tabs, buttons, etc.

The device data 205 contains the data values for device parameters configured through the universal DTM 200 or a universal BTM 210. The device data 205 is potentially either for a device template or for a device instance. The screen customization descriptions 207 specify customized screens defined by users including, for example, new tabs, security and access information displays.

The presentation objects 206 support user interface interactions for the universal DTM 200 (described further herein below with reference to a set of exemplary graphical user interfaces) in accordance with user-specified customizations, provided by the screen customization descriptions 207, to a default graphical user interface specification provided by the default device template 209 using the device description 211 and common file format 213. The business object 204 is a server component and, in addition to supporting interactions with the presentation objects 206, supports interactions between the universal DTM 200 and external components. Customized behavior of the business object 204 for a selected device/type template is defined by a set of device/type-specific parameter values retrieved from the device data 205.

In accordance with an embodiment of the present invention, both the universal DTM 200 and the universal BTM 210 are defined and created for a particular specified device type template/instance, on-demand, by default definitions from the default device template 209 and a specified DD provided from device descriptions 211 via a DD Engine 212. The DD engine 212 also provides access to device information maintained in CFF data 213. The BTM 210, including BTM business object 214 and presentation objects 216, operates upon blocks associated with device templates and instances represented in the universal DTM 200 in a manner analogous to the operation of the universal DTM 200.

The engineering database 202 is also a source of vendor-provided DTMs 215. In contrast to the universal DTM 200, which is capable of supporting any device for which a standard Fieldbus Foundation device description (DD) is provided, the vendor-provided DTMs comprise statically defined DTMs that are intended to provide engineer access to the configuration/run-time parameters of a particular device type.

Examples of external components to which the business object 204 communicates include: a Comm DTM 208, block type managers (BTMs)—including a universal BTM 210, and the device description (DD) engine 212. The DD engine 212 provides requested device descriptions and common file format files. BTMs provide access to block information associated with a designated FF device/type. The function blocks of a field device are described by BTMs that are child objects of the universal DTM 200. The Comm DTM 208 facilitates communications between the universal DTM 200 and field devices. The business object 204 also supports communications between the universal DTM 200 and the BTMs. Interfacing to the frame application, within which the universal DTM 200 operates, is through the FDT DTM interfaces (described herein below).

With continued reference to FIG. 2, the business object 204 carries out a variety of functions in support of the overall universal DTM 200's functionality. The server functions supported by the business object 204 are potentially used by frame applications without user interaction. The business object 204, in an exemplary embodiment, implements as many functions as possible, thereby allowing a slim implementation of the presentation objects 206. The following exemplary list of functions is implemented by the business object 204.

-   -   Administering device parameters and attributes     -   Interacting with interfaces to communicate with a device         (upload/download parameters) via Comm DTM 208     -   Maintaining channel objects that communicate with BTMs 210     -   Interacting with the DD Engine 212     -   Supporting device parameter access services     -   Comparing old/new/requests device parameter values     -   Implementing the core FF FDT Interfaces     -   Generating device documentation     -   Storing device parameters

The business object 204 provides the FDT interfaces required to store/restore parameters to/from the device data 205. In further support of the editing functionality provided by the universal DTM 200, an old value (before the editing) is maintained for each parameter. Furthermore each parameter will have status information for each data source by specifying a parameter status of the parameter within the project (storage) database and the device data 205.

Turning to the functionality of the presentation objects 206, when invoked the presentation objects 206 load a set of device parameters from the business object 204. Exemplary device parameter value types provided by the business object 204 to the presentation objects include: names, labels, descriptions, units, data types, security/access information—each parameter has an attribute to control read and write access of each parameter in a displayed security/access grid for a device template/instance. The presentation objects 206 maintain a separate (temporary) “edit” database with regard to device parameter values that facilitate a variety of user interaction modes described herein below.

User Interaction Modes

-   -   Edit Mode: This mode distinguishes the granularity in which         parameter changes will be written into the database (storage or         device database):         -   Block Mode:         -   The user is able to change several parameters in the             different tabs of the presentation object. Selecting the             Save button writes the changes to the business object 204             database 205 and in a frame application database. If the DTM             is connected to the device it is also possible to work in             this mode. Changes are only downloaded to the device when an             “Apply” button is pressed. If the user presses cancel button             the changes are lost. If the device is connected and the             user presses the ‘Direct Mode’ button the UDTM GUI switches             to the ‘Direct Mode’ user interaction style.         -   Direct Mode:         -   The Direct Mode is used for immediate change of single             parameter values. After the user changes a parameter and             leaves the input control for this parameter, the parameter             is validated and written into the database. The direct mode             is only available when the device is connected. If the             device is connected and user presses the ‘Block Mode’ button             the UDTM GUI switches to the ‘Block Mode’ user interaction             style.     -   Connection mode: In this mode the following states are         distinguished:         -   Not connected (sometimes called Off-line): The universal DTM             is not connected with a device. There is no             communication/data exchange with the device.         -   Connected (sometimes called On-line): The universal DTM is             connected with a device. There is communication/data             exchange between the universal DTM and the device.         -   Device templates are always offline

The default template for the presentation objects 206 of the universal DTM 200 includes a set of buttons supporting user interaction. The default set of buttons provided for presentation objects 206 include the following:

-   Save: is available on the screens where DTM data can be changed. The     save button will trigger a request to the frame application to save     the current DTM data to the database. -   Download: Write to the device parameters which have been modified by     the user -   Download All: Write to the device all parameters which the     customization has marked as downloadable parameters. The write     occurs regardless of whether the parameters have been modified -   Upload All: Read from the device all parameters which the     customization has marked as uploadable parameters. Parameters are     not written to the database until a Save is done.

With continued reference to FIG. 2, set of program interfaces are provided that facilitate invoking various functions supported by the displayed components. The following interfaces are implemented by the exemplary universal DTM 200 to carry out functionality described herein regarding the lifetime management of field devices via a generalized device management utility. In an exemplary embodiment depicted in FIG. 2, the following interfaces are supported:

FDT DTM interfaces 300 correspond to the mandatory interfaces for any DTM (universal or vendor supplied). The mandatory interfaces include a set of well known interfaces:

-   -   IDtm—The primary interface used to interact with DTMs. This         interface provides the ability to get other interfaces         implemented by the DTM. This interface provides the functions         required to start up a DTM. This interface also provides         functions to get the list of user interface actions supported by         the ActiveX presentation objects which are part of the DTM.     -   IDTMActiveXInformation—The interface used to retrieve a pointer         to the ActiveX presentation object of the DTM which implements a         supported function of the DTM.     -   IDtmInformation—The interface used to query the DTM for         information on what devices it is capable of configuring

FDT BTM interfaces 301 comprise the mandatory interfaces for any BTM (universal or vendor supplied). The mandatory interfaces include a set of well known interfaces:

-   -   IBtm—The primary interface used to interact with BTMs. This         interface provides the ability to get other interfaces         implemented by the BTM. This interface provides the functions         required to start up a BTM. This interface also provides         functions to get the list of user interface actions supported by         the ActiveX presentation objects which are part of the BTM.     -   IDTMActiveXInformation—The interface used to retrieve a pointer         to the ActiveX presentation object of the BTM which implements a         supported function of the DTM. This is the same interface as         defined for DTMs     -   IBtmInformation—The interface used to query the DTM for         information on what devices it is capable of configuring

The universal DTM 200 also includes a set of well known FDT Channel Interfaces 303 that represent mandatory interfaces for communication. These interfaces include:

-   -   IFdtCommunication—This is a standard FDT 1.2 interface which is         the primary interface through which read and write requests are         transmitted.     -   IFdtChannelSubtopology—This is a standard FDT 1.2 interface         which is the interface that provides the functions through which         the DTM implementing the channel interface is informed of the         DTMs or BTMs that will be using the channel interface.

FDT interfaces are provided for notification of communication completion. In the illustrative embodiment the well known FDT IFdtCommunicationEvents interface 302 is implemented by DTMs or BTMs to receive notification when read or write requests complete.

FDT interfaces are provided for notification of events to a host application (or another other interested external entity. In the illustrative embodiment, IDtmEvents 304 is an FDT 1.2 standard interface for sending event notifications from a DTM to the requesting entity.

Private DTM interfaces between business objects and presentation objects of a universal DTM or BTM, described further herein below, support exchanging information between the business object 204 and presentation objects 206 implementing ActiveX controls, or the business object for a universal BTM 214 and the presentation object 216.

The mandatory portions of the FDT (1.2) interface 300, 301, 302, 303, and 304 are well documented and therefore will not be specifically described herein. In addition to mandatory interfaces of the FDT 1.2 specification, the universal DTM 200 implements the following optional interfaces:

-   -   The universal DTM 200 implements the function         IDtmDiagnosis::Compare     -   This function allows comparing two offline device databases. It         is a business object function and could be used by applications         for comparisons.     -   The universal DTM 200 implements the function         IDtmOnlineDiagnosis::Compare     -   This function allows the comparison of an offline device         database with the online device data. It is a business object         function and could be used by applications for comparisons.     -   The universal DTM 200 implements a IDtmDiagnosis::InitCompare         method     -   This method defines the meaning of “DTMs of the same type” for         purposes of determining whether two DTMs are of the same type,         and therefore eligible for compare object. Two DTMs are of the         same type when:         -   the second DTM for the comparison specifies a same vendor             name/ID         -   the second DTM has the same required Bus Protocol         -   the second DTM has the same Manufacture-ID,         -   the second DTM has the same Devicetype-ID         -   the second DTM has the same Subdevice-Type, if available

If all the checks are successful, then the InitCompare method returns true and a compare of the DTM instance data sets is permissible.

-   -   The universal DTM 200 implements         IDtmOnlineDiagnosis::GetDeviceStatus     -   This function retrieves the device status and returns a list         with the latest status indications in user readable text form.         It is a business function (without user interface) and could be         used by applications to get the detailed device specific status         information.     -   The universal DTM 200 implements the functions         IDtmParamter::GetParameters and SetParameters     -   This function allows the frame applications to retrieve and         store the device parameter information (detailed parameter         information).

Additionally the universal DTM 100 implements the following FDT 1.2.1 specified interfaces: IDtmSingleDeviceDataAccess and Interface IDtmSingleInstanceDataAccess.

The function block functionality in an FF device is described with BTMs. BTMs are child objects of the universal DTM 200 and are connected to communication channels supported by the universal DTM 200. The universal DTM 200 uses a DD Engine 212 interface (I_Device 305) to identify which and how many block types could be connected to the universal DTM 200. For each device type, the DD Engine 212 creates, based on the information coming from the CFF file for each block, a unique UUID. The universal DTM 200 uses the DD Engine interfaces to retrieve the UUIDs for the possible block types and creates for each a channel object. Each channel object uses one unique block type UUID as a ‘supported protocol’ ID to identify which block type could be connected. For each possible block connection a channel object is created by the universal DTM 200. The UUID information is used as a block protocol identifier between the universal DTM 200 and a universal block type manager of the set of BTMs 210.

Standard FDT topology mechanisms and interfaces are used to assign a BTM to a DTM. If the DTM has child BTMs, it acts as a gateway. Mechanisms of nested communication defined in the FDT Specification are used for communication between the BTM and the DTM. If a DTM must create a BTM, it uses the standard interface IFdtTopology of the frame application. The frame application instantiates the BTM. Verification of assigned Child-BTMs performed by invoking the ValidateAddChildo method in the DTM of the IFdtChannelSubTopology interface. The frame application handles the instantiation of the BTMs.

The universal DTM 200 implements a private interface, I_DtmBusinessObject 307 that allows for the exchange of information between the business object 204 and the presentation objects 206 (e.g., ActiveX control presentation objects). A universal BTM of the BTMs 210 uses the same interface to access the private business object 204 information. For this the universal BTM implements an object with a callback interface to get notifications from the business object 204. Using the interface I_DtmBusinessObject 307 the Universal BTM is able to access some additional (private) information from the universal DTM 200.

-   This information can be     -   Device Type related     -   Device Instance information—the device tag, device ID, etc.     -   Block Type and instance related -   Device Type related information includes:     -   Device Type     -   Device identification information (Device Manufacturer, device         type, version, DD and CFF versions) -   Device Instance information includes:     -   Device Tag     -   Device ID     -   Device Address     -   Overall device status     -   Resource block mode

The above-identified information is stored in the universal DTM 200 as parameters. The universal BTM uses the universal DTM 200 interface function getParameterValue to access any parameter in the universal DTM 200.

A set of enumeration operations are defined that enable retrieval of parameter. statuses and values from the universal DTM 200 and for notification callback functions to give notification of any value and/or status changes:

-   paramStatus: Enumeration type that is a superset of all possible     status values for database sources. Depending on the selected     database source not all values are applicable:     -   initial: value is initialized after INIT by device default         values     -   storageLoaded: value is loaded from storage (project DB)     -   storageSaved: value is saved into storage (project DB)     -   uploaded: value is uploaded from device (device DB)     -   downloaded: value is downloaded into device (device DB)     -   uploadFailed: value failed to be uploaded from device (device         DB)     -   downloadFailed: value failed to be downloaded into device         (device DB)     -   dynamicUpdated: value is successfully uploaded from the device         in cyclic manner     -   dynamicUpdating: upload of the cyclic value is in work     -   insecure: cyclic upload of the value timed out. The device         database value contains the last valid value and is insecure.     -   editError: temporary value has caused an error condition after         editing     -   matching: temporary value matches the value in data source after         editing     -   modified: temporary value is not equal to the value in data         source after editing     -   userConfirmationNeeded: value needs confirmation by the user. It         changed because a related parameter caused a change of this         parameter (change of units or ranges)

A list of functions and methods are enumerated below that are supported by the private universal DTM interface I_DtmBusinessObject 307 supported by the business object 204.

-   Attach: is a function that facilitates obtaining configuration     information from the business object 204. The caller provides a     callback interface as parameter, and the function returns an     identifier ocxid to be used as argument ocxid of all other interface     methods. This function also returns additional information and     interface pointers to an xml manager and the FDT container within     which the business object 204 operates. -   Detach: disconnects the requestor from the business object 204. -   isOnline: checks whether the business object 204 is online. -   getLanguageId: Returns languageid of the business object 204. The     language ID must be used to load language specific resources -   InvokeFunction: allows invoking a specified function supported by     the business object 204. -   runningFid: the presentation objects 206 notify the business object     when an invoked function with a specified function ID is running.     The handled function id is set after extracting the functional     document -   getParameterDescription: obtains parameter information e.g.     description, parameter group, tokenized string if available and a     device parameter description including a number of fields defining     properties of the identified parameter. -   getParameterValue: provides a requested parameter value as a     variant, thereby allowing reading of any identified business object     parameter value. -   setParameterValue: sets an identified parameter value. If the     request fails, an error message is returned. -   getParameterAsString: provides a requested parameter value as a     string. -   setParameterAsString: sets an identified parameter value using a     string value. If the parameter value is not valid, then an error     message is returned. -   isActualParameterValue: determines whether actual parameter value in     the device and the temporary value of the parameter are equal -   getActualParameterValue: provides the actual (device) parameter     value as a variant. -   getActualParameterAsString: provides actual (device) value as a     string -   getDefaultParameterValue: provides the default parameter values as a     variant. -   getDefaultParameterAsString: provides the default parameter value as     a string. -   GetParameterLabel: provides the parameter label (for displays) of an     identified parameter. -   GetParameterUnit: provides the unit of a parameter. If the parameter     does not have a unit the returned string is empty. -   GetParameterMaxLength: provides the maximum length of an identified     parameter. This is needed for parameters which do not have fixed     length. -   GetParameterEnumQualifiers: converts, using the EnumQualifierString,     an enum ordinal value to an enum string -   VerifyParameters: verifies the identified parameters (if     verification is available). -   GetNParameters: provides the current number of parameters in the     business object 206. -   GetParameterName: provides a name of a particular (indexed)     parameter within a parameter list. -   GetParameterNames: provides a list of names of all parameters that     contain a specified search string in their name. -   SetParameterModified: sets the modified flag of a parameter. -   UploadParameterListStart: starts uploading specified device     parameters to a presentation object. -   UploadParameterAllStart: starts uploading all device parameters to a     presentation object. -   DownloadParameterListStart: starts downloading specific device     parameters. If a directdownload flag argument is true, then no     device state handling (Pre and Post download actions) is performed.     If a modified flag is set to true, only the modified parameters will     be downloaded. -   DownloadParameterAllStart: starts downloading all device parameters     for an identified presentation object. If the directdownload flag is     true, then no device state handling (Pre and Post download actions)     is performed. If the modified flag is set to true, then only the     modified parameters will be downloaded. -   DownloadParameterGroupStart: starts downloading all device     parameters of a group. If directdownload is true, then no device     state handling (Pre and Post download actions) is performed. If the     modified flag is set to true, then only the modified parameters will     be downloaded. -   RegisterCyclicParameter: Parameters could be registered in the     business object 204 to be uploaded in a cyclic manner. The upload is     done by the business object in the specified cycle on its own. With     this function it is possible to register parameters for cyclic     uploads from the device. If cycle is 0, parameters are removed from     cyclic processing. With cycle=1 the parameter is automatically     uploaded from the device by the business object 204 with the fastest     update cycle. With cycle=2 the update will be done in every second     cycle. Via a callback interface method     OnRegisteredParametersChanged, an associated presentation object     receives a notification when the upload of the cyclic parameters is     completed. -   PauseMeasurement: pauses cyclic uploading of parameters. This is     needed for activities like calibration steps, which should not be     disturbed by a cyclic upload of parameters. -   ResumeMeasurement: resumes measurement after successful completion     of a PauseMeasurement function. -   GetLastDeviceStatus: provides the last retrieved fieldbus specific     device status value. -   AuditTrail_StartTransaction: marks the start of an audit trail     transaction. -   AuditTrail_EndTransaction: marks the end of an audit trail     transaction. -   AuditTrail_Enabled: determines whether an audit trail for a device     DTM is supported and returns the availability of audit trail     functionality. -   AuditTrail_FunctionEvent: enters an audit trail function event entry     into the audit trail system. -   AuditTrail_DeviceStatusEvent: enters an audit trail device status     event entry into the audit trail system. -   LockDataSet: locks the business object 204's data set (allows write     access to parameters). This locking is used to coordinate parameter     changes between different presentation objects. -   UnLockDataSet: unlocks the business object 204's data set. -   GetNTrendParameters: returns the number of device parameters which     are marked for trending -   GetTrendParameter: returns information for the device parameter for     trending for an id number. The id number is between 0 and     (getNTrendParameters( )−1). The information is needed to set up the     scales and axis description of the trend curves. -   GetHelpfile: returns the name of a help file for a device DTM. -   TraceMessage: sets a trace message within the business object 204. -   GetProtocolParamlength: retrieves the protocol specific parameter     length for parameters. -   GetDataLength: retrieves the protocol specific data length (size)     for a certain data type. -   DeviceCommandStart: sends a protocol specific command directly to     the device. -   getNavigationDocument: returns an xml document to configure     navigation. -   GetUserInformation: provides an FDT user information data structure. -   PrivateDialogEnabled: returns information from a private dialog. -   OpenActiveXControlRequest: calls a function in the business object     204 from one of the presentation objects 206 to start another     presentation object instance. -   getCompareDTM: provides a pointer to a DTM selected within the     previously described IDtmDiagnosis::InitCompare method. -   GetParameterSecAttrOPAccess: provides security attributes for     functions and screens. For each universal DTM function and screen     there is a security parameter that holds the access information     (notvisible, disabled, enabled) for each user level (observer,     operator, maintenance, planningEngineer) and the Administrator or     OEM-Service qualifier. -   SetParameterSecAttrOPAccess: sets the security attributes for     functions and screens. For each universal DTM function and screen     there is a parameter, which holds the access information     (notvisible, disabled, enabled) for each user level (observer,     operator, maintenance, planningEngineer) and the Administrator or     OEM-Service qualifier. -   GetParameterSecAttrRWAccess: provides security attributes for a     parameter. Each parameter holds the access information (nv=not     visible, ro=read only, rw=read/write) for each user level (observer,     operator, maintenance, planningEngineer) and the Administrator or     OEM-Service qualifier. -   SetParameterSecAttrRWAccess: sets the security attributes for a     parameter. Each parameter holds the access information (nv=not     visible, ro=read only, rw=read/write) for each user level (observer,     operator, maintenance, planningEngineer) and the Administrator or     OEM-Service qualifier. -   getParamStatus: provides the status information for a specified     parameter paramName and database source. -   getParamAllStatus: provides all status information for a specified     parameter. -   getParamStatusAndValue: provides a temporary value and the status     information for a specified parameter paramName and database source. -   getParamAllStatusAndValue: provides a temporary value and all status     information for a specified parameter paramName.

With continued reference to FIG. 2, a callback interface IdtmEvents 304 is implemented by any entity that seeks to receive notifications from the business object 204.

-   OnUploadFinished: the client of the callback interface receives a     notification when an upload of parameters has finished. A success     flag indicates whether the upload operation was successful. -   OnDownloadFinished: the client of the callback interface receives a     notification when a download of parameters has finished. A success     flag indicates whether the download was successful. -   OnOnlineStateChanged: enables the client of the callback interface     to receive a notification when the online state of the business     object 204 changes. -   OnParamChanged: enables the client to receive notification of any     changes of the temporary value and/or the status information for a     specified parameter (paramName) and database source. A source     argument identifies which data source value and/or status changed.     Upload and download actions may trigger OnParamChanged notifications     with the database source flag set to databaseSource::device. Project     save or project load actions may trigger OnParamChanged     notifications with the database source flag set to     databaseSource::storage. Edit actions may trigger OnParamChanged     notifications with the database source flag set to     databaseSource::All, because the temporary value changed compared to     all (both) data sources.

The interfaces supported by the universal DTM 200 to the DD engine 212 (I_Dde 306 and I_Device 305 interfaces) enable the universal DTM 200 to obtain device type specific information from the DD and CFF files managed by the DD engine 212. I_Dde 306 is the main interface for the DD engine 212. The I_Dde interface 306 provides exposes methods for initializing the DD engine 212 and exposing the common information for the overall program behavior. The I_Device interface 305 provides an interface for device handling such as getting device information, block information, global device parameter information, system management information, network capabilities, etc.

Having described an exemplary architecture for the universal DTM 200 embodying the present invention, attention is directed to FIG. 3 wherein a flowchart summarizes a set of steps for dynamically building the universal DTM 200 within a frame application implementing FDT interfaces. The series of steps provided in FIG. 3 further illustrate the dynamic/on-demand nature of building a customized universal DTM. Initially, during step 310, a host application such as INVENSYS' IACC receives an initial command via a graphical user interface to create a customized universal DTM based upon a specified device template or instance (see, FIG. 4 described herein below). In the illustrative example, the device types are all Fieldbus Foundation device types, and the breadth of device types handled by the single universal DTM is confined to devices within the FF class. However, in alternative embodiments, the universal DTM is expanded to handle an extensible set of classes.

In response to the received request, at step 320 the host application starts up the business object 204. Thereafter, at step 330, the host application defines the Device Description and the Common File Format entries to be retrieved via the DD Engine 212 corresponding to a device type associated with the previously user-specified device type, and the appropriate DD and CFF files are thereafter obtained. The DD and CFF define, at least in part, the customized aspect of a default DTM associated with the universal DTM 200.

After obtaining the appropriate DD and CFF files via the DD engine 212, at step 340 the universal DTM business object 204 uses the device information in the retrieved device description and the common file format files to generate a parameter set for populating placeholders within the specified device template (applicable to all FF devices) based upon the DD and CFF information corresponding to the identified FF device type.

During step 350, to the extent that the user has selected a non-default pre-existing template upon which the customized universal DTM is to be based, data for the device template is retrieved from the device data 205 portion of the engineering database 202. In an illustrative example, the host application utilizes the FDT DTM Interfaces 300 in the DTM business object 204 to set the device template data within the customized universal DTM. If there is no device template data in the engineering database 213, the default values specified in the common file format and the device description are used for the parameter set values. If there is template data in the engineering database 202 corresponding to the selected template, then the values from the device data 205 entry is used to set corresponding values of the parameters for the customized universal DTM.

Next, at step 360, user interface definitions are retrieved for the device template from the user defined DTM screen customization descriptions 207 portion of the engineering database 202.

In step 370, the universal DTM Presentation object 206 generates a graphical user interface display corresponding to the selected template using the user defined DTM screen definitions and parameter data set in the universal DTM business object 204.

By way of example the host application retrieves a pointer to the presentation object 206 of the universal DTM 200. The pointer corresponds to a first screen presented (the “Home Page” described further herein below with reference to FIG. 5) from the business object 204. The presentation object 206 is used to display the first screen for the customized universal DTM. The presentation object 206 retrieves parameter values and information associated with the selected device template/instance from the business object 204. Furthermore, the presentation object retrieves user interface definitions associated with the selected device template/instance from the screen customization descriptions 207.

Once the customized universal DTM is created on-demand by a user's selection via a host application, the user can select one of a set of option tabs to access particular types of information associated with the device template/instance. These functions/capabilities are described herein below with reference to FIGS. 6-9. Thus, in accordance with an embodiment of the present invention, customization information is applied to a default universal DTM shell to render a customized universal DTM. The customization information is obtained from various sources, including DDs, CFFs, user-defined device data and screens to render, on-demand, a customized universal DMT for performing any of a variety of operations relating to lifetime management of FF device instances. Such operations include: creating new device type-specific templates from a default template, deriving and saving application-specific templates for previously created device type-specific templates, and managing on-line field device instances via device instances created from the previously defined templates.

Having described an exemplary architecture for the universal DTM 200 embodying the present invention as well a method for building the universal DTM 200, attention is now directed to a set of graphical displays associated with various aspects of the universal DTM 200's operation. FIG. 4 depicts an exemplary graphical user interface provided by an exemplary frame application, embedded within INVENSYS I/A Series Configuration Component (IACC), from which a user launches the universal DTM 200 for a selected target device. The frame application also provides FDT compliant interfaces for the universal DTM 200 once it has been launched.

The universal DTM 200 operates upon device templates derived from a default template or any other parent template. The hierarchical inheritance/derivation relationship between various device templates, and instances created from the templates, follows the hierarchical arrangement of the tree structure depicted in the system pane 400. In particular, a FF Devices node 402 on the tree of system elements is associated with a default FF device template that defines a default set of behaviors for the universal DTM 200 when operating in a Fieldbus Foundation device context/mode. Each of the child nodes under the FF Devices node 402 (e.g., “BA30”) is associated with a template derived from the default FF device template. Each child template is characterized by the default template specification and a set of modifications to the default template to render the child template. A user defines such child nodes by selecting the parent node (in this case the FF devices node), right clicking to expose a context menu 403, and then selecting the “New Definition” option 404. Thereafter, the user is prompted to provide a name for the new template (for display on the tree) as well as other information (including a DD file) associated with the child template. The derived template is saved as a child node of the template node from which it is derived. An inheritance relationship is thus established between a parent template and all children derived there from.

While only one level of derived FF device templates are depicted in FIG. 4, the system described herein is capable of handling several hierarchical derivation levels. For example, selecting the “+” symbol under any of the other three child nodes under the FF Devices (default template) node, a second level of derived templates are revealed. Such template inheritance can be applied to render a set of application-specific device DTMs. For example, a pressure transmitter DTM template can have a set of application-specific child templates for use in flow, tank level, and pressure applications.

Supporting hierarchical template definitions provides a number of advantages. One or more levels of derivation can be used to incorporate application-specific knowledge into more generally defined parent (e.g., device-specific templates)—information that would otherwise need to be provided by a commissioning engineer in the field. At each level, the information defined for a device becomes more specific. Including application-specific information in one or more levels of child device templates can thus save time when deploying or replacing devices as well as reduce the knowledge load on device commissioning agents. Such use of a hierarchy of templates with various degrees of application-specific knowledge applied at the various levels, in the context of the universal DTM 200, also facilitates standardizing device configuration across a project or enterprise by ensuring a certain degree of common behavior/operation of devices used in similar applications. Such standardization cannot otherwise be assured in without time-consuming/exhaustive review of potentially very large numbers of parameter values assigned to hundreds or even thousands of devices distributed across an enterprise.

Selecting FDT on the context menu 403 exposes an FDT sub-menu 406. In the illustrative example, the FDT aspect of the IACC system supports both vendor-specific DTMs and universal DTM implementations for selected device types. Selecting the Associate Vendor option on the FDT sub-menu 406 enables a user to launch any one of potentially multiple vendor-coded DTMs within the IACC frame application. Such specialized vendor-developed/coded DTMs are well known in the art and will not be discussed further herein. However, if a user instead selects the FDT Editor (Universal) menu option on the FDT sub-menu 406, then the universal DTM 200 embodying the present invention is launched, on-demand, based upon the currently selected template node (BA30) and a standard DD provided from a library of standard DDs managed by the DD engine 212. In contrast to known DTMs, the universal DTM 200 is customized on-demand to a specific device type, at the time it is launched by a user's input. The device-specific customizations to the universal DTM 200 are based upon a DTM template (corresponding to the currently selected node on the system tree within pane 400) and the associated standard DD associated with a device type associated with the DTM template. By deriving from a common default behavior, the resulting customized universal DTM interfaces share a common base functionality and look-and-feel for users.

When a customized universal DTM is initially launched within a frame application, a first screen or “home page” graphical user interface 500, of a type depicted in FIG. 5, is generated by the presentation object 206. The home page graphical user interface includes a variety of status notifications as well as an initial set of information associated with the DTM customization template/instance and DD incorporated dynamically, on-demand into the universal DMT 200 at the time of launch.

In accordance with a default user interface specification, the graphical user interface for the universal DTM 200 includes an information tab 502 that is automatically selected when the on-demand customized universal DTM is launched. In the device information screen device identification and more general information about the device type represented by the template (or device instance created from a device-specific template) are displayed. A device tree 504 represents blocks associated with the current device type as a set of sub-nodes under a device template root name (e.g., Foxboro.RTT25-F2.020101). Selecting one of the block nodes under the device root launches a customized universal BTM instance to be launched and presentation of a block first screen (see, FIG. 10 described herein below) similar to the first screen for the customized universal DTM.

With continued reference to FIG. 5, a device identification pane 506 displays device type information from a DD and CFF obtained by the universal DTM 200 from the DD Engine 212. Such information includes: device manufacturer, device type, device version, DD version, and CFF file revision. The device identification pane 506 also provides specific device instance information including: device tag, device Address, and device ID. When the universal DTM 200 is connecting to a corresponding device it checks the device identification information against the loaded parameter values from the device.

A display box 508 potentially displays any of a variety of graphics displays associated with the specified device type referenced by the universal DTM 200. To enter a reference to a graphic (to be added to a list within a graphics files pane 510) the user clicks on an Add button. In a resulting popup menu the user selects a File Open option. With a resulting standard File Open Dialog the user navigates through a system directory and selects a file. Afterwards a dialog opens to let the user define whether the graphics should be instance or device type specific. To delete an entry the user selects the appropriate text reference within the graphics files pane 510 and presses a delete button. To display the information the user selects the reference. The graphics are thereafter rendered in the display box 508.

A links box 520 enables a user to enter electronic data links to any of a variety of information sources including URL's, network/file names, etc. referencing documentation in any of a wide variety of formats (e.g., .pdf, .bmp, .rtf, etc.). A user enters a link within the links box 520 by clicking on an Add Button. In a resulting popup menu the user selects File Open. With a resulting standard File Open Dialog the user navigates through a system directory and selects a file. Afterwards a dialog opens to let the user define whether the linked file/document should be instance or device type specific. To delete an entry the user selects the appropriate text reference within the graphics files pane 520 and presses a delete button. To display the information the user selects the reference, and the resulting information is rendered in a viewing application that is launched in response to the selection (e.g., a .pdf viewer application).

A device type comments box 530 enables a user to enter textual information for the device type. It will be stored and be visible for all device types. Edit functions are supported for adding or changing text within box 530. The text within the device type comments box 530 is stored with any other customization data associated with the particular derived template when the derived template is stored.

A device comments box 540 enables a user to enter textual information for a particular device instance. The content displayed within the device comments box 540 is only visible for the particular device instance, if any, associated with the current customized DTM instance. The instance specific information is stored with all other parameter values with the FDT interfaces for persistence data in the frame application's database. This information persists with the device instance and is not tied to any template.

Other types of materials potentially accessible from the first screen 500 for the customized universal DTM include: other applications, status buttons (e.g., on-line/off-line), general health, alarms, and block modes. The first screen graphical user interface 500 provides an extensible platform for providing summary information to a user without having to navigate through a number of user interfaces.

The first screen user interface 500, while initially exposing the contents of an “information tab 502, supports an extensible set of additional tabs—each providing a particular type of information relating to a specified device type template or instance. In the illustrative example, the set of tabs include: system management, network management, diagnostics, and security. Each of these types is described herein below with reference to FIGS. 6-9.

Turning to FIG. 6, an exemplary system management graphical interface 600 is provided by the customized universal DTM when a user selects the “SM” tab on the first screen graphical user interface 500. The system management graphical interface 600 provides access to a variety of system management parameters associated with the customized universal DTM. Parameters that are changeable in off-line mode include Device ID, Device Tag, Operational Powerup, T1, T2, and T3. The parameters Clock Sync Interval and Macrocycle Duration are only changeable if the device is a configuration master. A link master assigns the Device address, but the user should be able to change it.

Turning to FIG. 7, an exemplary network management graphical interface 700 is provided by the customized universal DTM when a user selects the “NM” tab on the first screen graphical user interface 500. The network management graphical interface 700 only displays information relating to the network when connected on-line to an actual field device corresponding to the customized universal DTM operating in association with a field device instance and its associated device information provided by the DD engine 212.

Turning to FIG. 8, an exemplary diagnostics graphical interface 800 is provided by the customized universal DTM when a user selects the “Diags” tab on the first screen graphical user interface 500. The diagnostic screen, rendered when a user selects the Diags tab, presents the overall status of the device. Like the NM tab, the Diags tab operates in conjunction with an on-line device instance. The diagnostic interface 800 presents, by way of example, the following:

Device identification information (including Device tag, device ID and device address in the header);

Device communication status (as reported by the system management);

Resource block status including Block_Mode and Block error information;

Transducer Block Status Including Block mode and XD error information;

Function block status including Block mode, Block error and Status and value for the connectable parameters; and

Communication statistics information (if supported by the device) In a background task the business object 204 periodically updates dynamic status values from the associated on-line device instance corresponding to the customized universal DTM.

Turning to FIG. 9, an exemplary security graphical interface 900 is provided by the customized universal DTM when a user selects the “Security” tab on the first screen graphical user interface 500. As shown in the security graphical interface 900, the universal DTM 200 supports a set of configurable access levels that are displayed in the form of a parameter permission/modification matrix displayed in the device parameter matrix 910. The matrix 910 comprises a set of cells determining the ability of a set of identified classes of user to read and/or write parameter data associated with the device represented in the customized universal DTM. A Tabs matrix 920 defines user class access to content represented under each of the aforementioned tabs displayed on the first screen as well as each of the graphical user interfaces described herein with reference to FIGS. 5-9. A Functions matrix 930 defines the functions of the customized universal DTM that are accessible to the various user classes identified in the column headings. In the illustrative example, the Functions matrix identifies DD methods that can be invoked by different user classes as defined by their different roles in the project. Each device type can thus be associated with a corresponding permissions matrix.

The above-describe list of tabs is intended to be exemplary in nature. Thus, those skilled in the art will appreciate, in view of this disclosure the potential to add new tabs (either through programming or tool-based customization facilities) addressing other aspects of field device management.

Turning to FIG. 10, an exemplary universal BTM first page 1000 is illustratively depicted (in the present case for a transducer block, TR_(—)1 identified in the device/block tree). The interface contains much of the same information types and functionality described previously hereinabove with reference to the device first page 500. In the case of the universal BTM 210, the home page corresponds to an Identification tab. The associated screen depicted in FIG. 10 shows information concerning the instance of the block in “Block” section 1002. The Block section 1002 is initially loaded from a block description provided by the DD Engine 212. If the business object 214 is online, then the information is read from the block's parameter 0. The following information is available in this section:

-   -   Block type     -   Profile     -   Tag Description

A display box 1008 potentially displays any of a variety of graphics displays associated with the specified device type referenced by the universal BTM 210. To enter a reference to a graphic (to be added to a list within a graphics files pane 1010) the user clicks on an Add button. In a resulting popup menu the user selects a File Open option. With a resulting standard File Open Dialog the user navigates through a system directory and selects a file. Afterwards a dialog opens to let the user define whether the graphics should be instance or device type specific. To delete an entry the user selects the appropriate text reference within the graphics files pane 1010 and presses a delete button. To display the information the user selects the reference. The graphics are thereafter rendered in the display box 1008.

A links box 1020 enables a user to enter electronic data links to any of a variety of information sources including URL's, network/file names, etc. referencing documentation in any of a wide variety of formats (e.g., .pdf, .bmp, .rtf, etc.). A user enters a link within the links box 1020 by clicking on an Add Button. In a resulting popup menu the user selects File Open. With a resulting standard File Open Dialog the user navigates through a system directory and selects a file. Afterwards a dialog opens to let the user define whether the linked file/document should be instance or device type specific. To delete an entry the user selects the appropriate text reference within the graphics files pane 1020 and presses a delete button. To display the information the user selects the reference, and the resulting information is rendered in a viewing application that is launched in response to the selection (e.g., a .pdf viewer application).

The GUI for the universal BTM 210 also includes a Configuration tab. Turning to FIG. 11, an exemplary configuration graphical interface 1100 is provided by the customized universal BTM 210 when a user selects the “Configuration” tab. When a configuration screen is displayed, the user is able to specify parameters in the block. A user names and builds configuration entries corresponding to the blocks of a field device by selecting parameters from a list of block parameters. The parameters of each identified block are identified by “parameter name” and current/last known value for the parameter is displayed in an adjacent column. A units column and help column are also included for storing additional information relating to the block parameters.

Turning to FIG. 12, an exemplary tuning graphical interface 1200 is provided by the customized universal BTM 210 when a user selects the “Tuning” tab. The tuning tab interface 1200 combines the characteristics of a “Configuration” tab and a “Watch” tab. The tuning interface 1200 allows a user to modify device parameters. The interface 1200 also displays parameter values within a chart of Block Parameters. The set of parameters are dynamically updated and displayed vertically over time. The tuning interface 1200 allows the user to see the effect of changes made to the parameters in real time. It is thus used for tuning the blocks.

Turning to FIG. 13, an exemplary watch graphical interface 1300 is provided by the customized universal BTM 210 when a user selects the “Watch” tab. The watch graphical interface 1300 displays a user defined set of parameters over time. The parameters are dynamically updated in a time sequence. Rather than showing the parameter and the current value it displays the parameter and the value over a span of time. The user can display the parameter values either in a grid (presently shown) or in a graphical plot.

Turning to FIG. 14, an exemplary diagnostics graphical interface 1400 is provided by the customized universal BTM 210 when a user selects the “Diagnostics” tab. The diagnostics graphical interface 1400 displays a user defined set of parameters. The parameter values are dynamically updated. The screen shows the parameter name and the current value for the parameter. The diagnostics graphical interface 1400 screen is thus used to display diagnostic parameters in a device which may be changing over time.

Turning to FIG. 15, an exemplary methods graphical interface 1600 is provided by the customized universal BTM 210 when a user selects the “Methods” tab. The device descriptions provided by the vendors, in addition to device parameter definitions, contain methods. The methods are a scripting like language written in device description language. These scripts are written by the device vendor to perform specific functions. The methods graphical interface 1500 shows the methods in the device description file and interacts with the DD Engine 212 to execute the method script.

Turning to FIG. 16, an exemplary security graphical interface 1600 is provided by the customized universal BTM 210 when a user selects the “Security” tab. As shown in the security graphical interface 1600, the universal BTM 210 supports a set of configurable access levels that are displayed in the form of a set of parameter, method, function and screen permission/modification matrices.

Having described an exemplary universal DTM/BTM facility for providing access to device/block parameters based upon identified device type, attention is directed to an enhancement to the aforementioned facility, in the form of a universal DTM/BTM customization tool. The customization tool facilitates modifying device editor definitions of existing device templates, through a set of graphical user interface screens, to define child templates having customized user access to device/block parameters that are presented via the universal DTM/BTM graphical user interface screens (described herein above). The same customization capability can be used to modify an existing device editor definition associated with a device template. To the extent that child templates exist, the children inherit the changes based upon value locking designations described further herein below. Furthermore, it is noted that the illustrative embodiment of the customization tool described herein below is directed to a universal BTM. However, the customization tool is equally applicable to the editor definitions associated with DTM.

The customization tool is used to modify an existing editor for a particular device template and store the customized version as a derived child device template. In a DTM/BTM editor application environment of the type described herein, an expert instrument engineer utilizes the customization tool to edit a previously created DTM/BTM editor definition to specify particular display screens and permissions associated with the editor interface for the particular device type associated with the device template. The changes can be directed, for example, to the permissions definitions associated with the device type's editor, thereby defining customized access to appropriate parameters by certain classes of individuals. For example, an operator's display screens include only device/block status information, while a process engineer's display screens provide read/write access to parameters for configuring and/or maintaining the field devices. The device template containing the modified editor definition is stored as a child template of the template from which it was derived within the engineering database 202.

Turning to FIG. 17, an exemplary graphical user interface is provided for a user with sufficient credentials to invoke a customization tool by selecting a Customize tab 1700 from a home page for a transducer block. It is noted that the customization tool is also invoked by selecting a Customize tab for a device from a graphical user interface provided by a universal device type manager. A customization main page displayed in FIG. 17 presents a set of user options for customizing the defined interfaces and permissions associated with the currently loaded editor for the device type template. In the illustrative example, the customization tool comprises a set of six views that are accessed by a set of corresponding buttons (e.g., Group Parameters 1702, Group Overview 1704, Define Tabs 1706, Tab Overview 1708, Set Parameters 1710, and Setup Downloads 1712). Each of these buttons and associated graphical user interfaces is described herein below.

Turning to FIG. 18, upon selecting the Group Parameters 1702 button, the customization tool presents a customization page/dialog that enables a user to categorize parameters. This provides a user the opportunity to arrange parameters on a user interface according to their use (e.g., configuration, diagnostics, calibration, process data, etc.). These user-customized parameter group definitions are potentially used to define the arrangement of parameters within other display screens of the editor utility for accessing/displaying field device information. By way of further example, the group designations are also used to enforce different access rights to various user classes/roles/tasks.

A set of previously defined groups is accessed via a Parameter Group box 1800. The Parameter Group box 1800 is, by way of example, a drop-down list (e.g., combo box) control that provides a list of currently defined parameter groups. The user selects one of the groups (e.g., Process) to reveal the current set of parameters assigned to the group, and modify the assigned set of parameters. The parameters presently assigned to the “process” set are displayed in box 1802. A user adds new parameters to the set by selecting one of the parameters in box 1804 and then selecting the add button 1806. The user removes a parameter from the set by selecting a parameter in box 1802 and then selecting the remove button 1808. The user stores/commits the modifications by selecting the “ok” button 1810 or leaves without making any changes by selecting the “cancel” button 1812. In the illustrative embodiment, a parameter is assignable to multiple groups. For example a parameter can be assigned to both a “diagnostic” parameters group as well as the “process” parameters group.

The Parameter Group dialog depicted in FIG. 18 also supports adding and removing groups. By way of example, selecting the “Group Names . . . ” 1814 button launches a dialog box that lists all the presently existing parameter groups. Controls (e.g., buttons) are included within the dialog box to enable a user to create a new parameter group and remove an existing parameter group.

Turning to FIG. 19, upon selecting the Group Overview 1704 button, the customization tool presents a customization page/dialog that enables a user to add/remove parameters from existing groups using a multi-column format and checkboxes. In the illustrative example, a parameter name field 1900 specifies a parameter of either a simple type or a structure including sub-parameters. Structure parameters are identified by a “+/−” sign adjacent to an index number in an index column 1902. When a “+” sign is selected, the structure is expanded to reveal sub-parameters.

Parameter Groups are identified at column headings. Each group's assigned parameters are indicated by checked boxes with the appropriate group column. A user can select any checkbox to change a parameter's membership status in any group. When a “show all parameters” checkbox 1904 is unchecked, the Group Overview dialog only lists parameters that have not yet been assigned to any group. Parameters assigned to a group will not be visible. This allows the engineer to determine which device parameters have not been assigned to any group and assign them.

Turning to FIG. 20, upon selecting the Define Tabs 1706 button, the customization tool presents a customization page/dialog that indicates associations between parameter groups and tabs—where the tabs correspond to a current set of pages/views of information presented by the customized device editor (e.g., Configuration, Diagnostics, Tuning, and Watch in FIG. 17). A user, via the Define Tabs dialog, creates new views to display particular groups of parameters. The interface in FIG. 20 shows the currently defined tabs and parameter groups. The dialog shows which parameter groups a tab displays and whether all parameters in the group are displayed or a subset. Furthermore, a user can select the “Tab Names . . . ” 2000 button to invoke a dialog for creating a new tab name of a particular tab type. By way of example, the Tab Names . . . dialog shows all of the tabs currently defined. Pressing a “New” button creates a new entry (tab/view) in a displayed tab list. A Remove button facilitates removing an existing tab (which may be blocked in the case of certain required tabs). Furthermore, a user can assign a “type” to a tab. By way of example, a set of four tab types are supported: configuration, diagnostic, tuning, or watch. Configuration tabs display parameters and allow an engineer to enter values. Diagnostic tabs read the current value from the device and display it to the engineer. They do not allow modifications to the displayed values. Watch tabs read values from the device and periodically update the display. Watch tabs show the parameter values changing over time. Tuning tabs contain two panes. A first pane acts like a configuration tab, allowing the engineer to modify device values. A second pane shows selected parameters changing over time.

After a tab name has been established (creating a new view screen) a user adds parameters to the tab/view by selecting a corresponding “Details . . . ” button presented under the appropriate column heading corresponding to the tab name. An illustrative dialog for editing the parameters associated with a named tab is presented in FIG. 21. Selecting the “Details . . . ” button causes the editor facility to display a dialog that shows parameters currently assigned to a tab. A combo box 2100 lists various classes of parameters to be displayed in the pool of available parameters on a left pane 2102. A right pane 2104 displays a set of parameters presently associated with the (Process) tab. The engineer selects parameters in the left hand pane and add them to the tab by pressing the “>>” button. After adding a parameter to the tab, the parameter is shown in the right hand pane. The engineer selects parameters from different groups to add to the tab. The engineer can also select parameters currently in the tab and remove them by pressing the “<<” button.

Turning to FIG. 22, upon selecting the Tab Overview 1708 button, the customization tool presents a customization page/dialog that displays a dialog that provides an overview of all the parameters and the selectable tabs/views within which they are presented. A single parameter can be presented on multiple tabs/views. The engineer uses the Tab Overview dialog depicted in FIG. 22 to assign a parameter to a tab by checking the check box under the tab column for a parameter. This has the same behavior as assigning parameters to a tab through the Define Tab dialog described herein above with reference to FIG. 21. The Tab Overview dialog in FIG. 22 does not allow the engineer to create or delete tabs. Only existing tabs can be seen. A “show all parameters” check box 2200, when unchecked, shows only parameters that are presently not assigned to any tab/view. Parameters assigned to a tab will not be visible. This allows the engineer to determine which device parameters have not been assigned to any tab and assign them.

Turning to FIG. 23, upon selecting the Set Permissions 1710 button, the customization tool presents a customization page/dialog that displays a dialog for facilitating defining access and security for parameters and tabs based on a user's class/task/role (referred to herein generally as “role”). The Set Permissions dialog replaces the Security tab presented in the embodiment depicted in FIG. 9. A Parameter pane 2300 shows all the parameters for the device. Roles are identified by column heading in each pane. The engineer specifies the access allowed to each user type based on their role. Parameter access can be set to be Read or Read & Write.

A Screen name pane 2302 facilitates specifying which tabs/views of the customized view sets are visible to particular roles. Thus, in the illustrative example “observers” will not have access to the Configuration, Compare, or Customize tabs/views on the customized device/block editor interfaces.

A Function name pane 2304 facilitates specifying operations supported by the editor such as adding notes about a device on a role/user-type basis. The engineer enables or disables the operation to be accessible to a user based on their defined role.

The parameter definitions for a device in a DD file do not specify whether parameters must be written to the device in a specific order. Nor do the parameter definitions specify a device mode that a device must be in for the parameter write to occur. Furthermore, after writing a parameter, a delay may be required before a next parameter is written to the device. Turning to FIG. 24, upon selecting the Setup Downloads 1708 button, the customization tool presents a customization page/dialog that displays a dialog that facilitates specifying parameter write operations. The Setup Downloads dialog displays a list of candidate parameters in a left hand pane 2400. The parameters displayed in pane 2400 are filtered by selecting a parameter group from a combo box 2402 that lists various classes, groups, types of parameters. As an example an engineer selects an entry within combo box 2402 to show only parameters in a “Process” group.

Parameters that are to be written to a device as part of a device download operation are designated by adding a parameter from pane 2400 to a writable list pane 2403. The download behavior is defined for each parameter in the writable list pane 2403 by designating a device operation mode within which the parameter can be downloaded. A delay after writing a parameter is also designated in a Wait column in pane 2403. The order of downloading a parameter is modified by selecting the parameter and pressing the “up” or “down” button adjacent to the pane 2403. These buttons move the parameters up or down in the middle pane display.

Furthermore, devices potentially undergo a commissioning operation. An example of such a commissioning operation is described in Bump et al. U.S. Ser. No. 11/403,224 entitled “Method and Supporting Configuration User Interfaces for Streamlining Installing Replacement of Field Devices” filed on Apr. 11, 2006. During the commissioning process a device is setup for initial plant operations. The commissioning process may not involve downloading all device parameters specified in the writable list pane 2403. Some parameters may be modified only as part of calibration operations or operations performed through device maintenance. The particular parameter values that are to be downloaded during the commissioning step are specified in a download list pane 2404. An engineer adds parameters to the download list pane 2404 from the writable list pane 2403 by selecting parameters in the pane 2403 and then pressing the “>>” button. Pressing the “>>” button makes a copy of the parameter in the right hand pane. In other words the parameter is shown both in the middle pane and in the right hand pane. The definition of write mode and time delay is used during commissioning by reading a value specified for the corresponding entry in the writable list pane 2403. Similarly, the engineer removes parameters from the commissioning set by selecting parameters in pane 2404 and pressing the “<<” between panes 2403 and 2404.

In addition to the above-described view customizations, the customization editor described herein also supports specifying default parameter values. Such values are specified by exposing the parameter in one of the tabs/views containing the parameter and entering a value. The values submitted during customization are stored in association with the definition of the customized child template.

Furthermore, value and editor interface customization locking is supported to prevent modifications to particular child templates and values assigned to particular parameters. Such locking is generally designated by an administrator. Locking is achieved by clicking on the lock icon shown next to parameters and buttons in the dialogs displayed in FIGS. 18-24 described herein above. A locked parameter prevents unauthorized engineers using the template or instances derived from the template, from modifying the customization or values. Thus, an expert instrument engineer can define a device template which allows the engineers using the templates to set up a device to modify or set only a very small number of parameters.

In a particular embodiment, the lock in the dialogs for a customized template implements the following lock paradigm:

-   -   Parameters Locked in Parent inherit value, and retain a link to         the value, in the parent. These parameters can not be modified     -   Parameters Locked in Me can be modified. These parameters do not         maintain a link to the value in the parent. These parameters         become Locked in Parent when the template is inherited     -   Parameters Unlocked can be modified. They do not maintain a link         to the value in the parent.

Having described a set of graphical user interfaces and functionality supported by an illustrative customization editor facility, attention is directed to an exemplary manner for storing the customized child templates defining an interface for accessing parameters associated with particular device types. In a particular illustrative embodiment, an engineer invokes a customization process by selecting a New Definition option on the context menu 404 (in FIG. 4) for an existing device type template (BA 30) to commence the customization process on a new child device template. This process is summarized in FIG. 25.

During step 2500 a child template is created from an existing device type template—which may itself be a child of yet another template. If the child template is derived from the generic root device (e.g., FF Device), then the user takes additional steps to associate the child device template with a device type including associated DD and CFF files for the device type of interest. This step is by-passed when creating child templates from existing templates that are already associated with a device type.

Thereafter during step 2502, assuming an engineer has a proper assigned role, the engineer utilizes customization tool interfaces described hereinabove with reference to FIGS. 17-24 to define the customized editor definition for the child device template. The child device template is then stored during step 2504 under the parent template from which it was derived.

As noted above, during step 2500, an association is established, if not already present, between the child device template and a device definition. This association facilitates presentation of the child template as a suitable device type (and thus editor) when creating a new device instance. The association facilitates automated filtering of device templates from which an engineer creates device instances for an actual hardware configuration. Multiple child templates can be associated with a same device description. This facilitates providing application-specific editors for a same device description. Finally, it is noted that since each device template has its own associated editor definition, an existing definition of an editor is modified by merely invoking the editor itself and then accessing its customization tab.

Turning to FIG. 26, a set of steps summarize the use of an instance of the child device template, including the customized editor definition, to provide a customized editor interface for the device instance for a logged on user having a particular role. During step 2600, an instance of the child device template, including a customized editor definition, is created for a particular device/block in a system. The instance is created, for example, when a user seeks to add a device (and its associated blocks) to a control system engineering database. At that time, suitable templates are presented to the user based upon, for example, a specified device type. The user selects one of the presented device templates.

Thereafter, during step 2602 a user invokes the customized editor on the device instance to carry out a task. The user, at the time of the request, has logged onto the system and has a set of associated roles that were previously defined by an administrator.

During step 2604, the host of the child editor passes the roles associated with the requesting user to the child editor instance. The child editor instance thereafter customizes the access provided to the user (including both the tabs and associated views displayed in FIGS. 17-24) based upon the provided roles.

It is noted that while the aforementioned exemplary steps in both FIGS. 25 and 26 refer to “devices” it is noted that the steps also describe the equivalent steps performed on blocks (e.g., Foundation Fieldbus blocks), and thus the term device is intended to encompass both devices and blocks.

Turning to FIG. 27, a Compare utility is exposed via the editor interface associated with a particular device type in accordance with an embodiment of the present invention. The compare utility extracts a copy of previously stored parameter values from the engineering database 202 for a device instance and compares those values to a set obtained from an actual live device. The copy of values from the database 202 is generally a default configuration, while the values from the live device have undergone some transformation, either intentional or inadvertent, to reside in a possibly faulty state.

The Compare utility user interface depicted in FIG. 27, and its associated functionality enables a user to view differences between the device configuration as stored in the engineering database and a current configuration in a physical device and any blocks in the device with a minimized degree of effort. Such comparison of values helps ensure the physical device is executing with an intended configuration. Conversely, the live values from a device may actually be the desired source of data for the engineering database 202. The Compare utility also facilitates updating the engineering database 202 if device maintenance dictates changes to the configuration. For example, the Compare utility corresponding to the graphical user interface depicted in FIG. 27 is used to review a set of configured settings against a standard/default set of parameter values for a device as part of a device commissioning procedure performed in the workshop.

In the illustrative embodiment, when a user selects the “Compare” tab 2700, the Compare dialog view is displayed by the editor facility. The dialog initially displays values from the engineering database in the Database Value column 2702. The Device Value column 2704 is initially blank. Thereafter, the compare utility invokes a series of read operations on the device associated with the currently executing editor facility to acquire corresponding parameter data from the device. The received data values are presented, upon receipt, within the Device Value Column. The Compare dialog view also contains a transiently depicted progress indicator (not shown in present view showing comparison results) that tracks the progress of reading device values from the device.

In an exemplary embodiment the device values are updated on demand using a Refresh button 2708. The refresh button 2708 is used, for example, to display new values as changes are made to the device.

Another aspect of the Compare utility and its associated dialog view is that the respective values from the database 208 and the device are compared after both have become available. A graphical indication (e.g., ≠, an unequal sign) is inserted in the column 2706 between the two values, and the corresponding parameter row is highlighted.

Furthermore, the Compare dialog supports filtering parameters. Examples of available filters include: display only parameters with non-matching values, display only a particular defined group of parameters, only selected parameters (indicated by checking the column on the left side of the dialog view. These filter modes are invoked by checking the appropriate box at the bottom of the dialog view. The last filter is to show selected parameters when the “Selections Only” box is checked.

The user can click on a row to select parameters. Once parameters have been selected, the user can elect to download the database value to the device by pressing a Download Sel button 2710. The user can also select parameters which will be written to the database to become part of the engineering configuration by pressing an Upload Sel button 2712 after selecting parameters.

In view of the many possible embodiments to which the principles of this invention may be applied, it should be recognized that the embodiments described herein with respect to the drawing figures are meant to be illustrative only and should not be taken as limiting the scope of invention. For example, those of skill in the art will recognize that some elements of the illustrated embodiments shown in software, stored on computer-readable media in the form of computer executable instructions, may be implemented in hardware and vice versa or that the illustrated embodiments can be modified in arrangement and detail without departing from the spirit of the invention.

While the illustrative embodiments have been directed primarily to FF Device Descriptions, the invention as recited herein below, and in particular the term device description, is intended to be broadly defined to include HART Communication Foundation EDDL, Fieldbus Foundation EDDL, and Profibus International GSD, among others, all collectively referred to herein as device descriptions. Therefore, the invention as described herein contemplates all such embodiments as may come within the scope of the following claims and equivalents thereof. 

What is claimed is:
 1. A method for creating customized definitions for user interfaces provided by a field device editor, the method comprising the steps of: maintaining in a device definition database a first device template corresponding to a device type, wherein the first device template includes a first definition of an editor interface for the device type; modifying the first definition of the editor interface via a customization tool associated with the editor interface for the device type, thereby rendering a modified version of the first definition of the editor interface; wherein the modifying step comprises customizing a download operation for commissioning device instances; and storing the modified version.
 2. The method of claim 1 wherein the modifying step comprises specifying groupings of parameters for use in the editor interface.
 3. The method of claim 1 wherein the modifying step comprises defining new screens to a set of interface screens associated with the field device editor.
 4. The method of claim 3 wherein the set of interface screens, including new screens added during the modifying step, are accessed via tab controls on the field device editor graphical user interface.
 5. The method of claim 1 wherein the modifying step comprises customizing permissions associated with particular user classes.
 6. The method of claim 1 wherein the storing step comprises storing the modified version as a child template of the first device template.
 7. The method of claim 1 wherein the customization tool is invoked via a control exposed by the editor interface for the device type.
 8. A physical computer readable medium including computer executable instructions that, when executed on a computer system including a display, provide an editor interface facilitating creating customized definitions for user interfaces provided by a field device editor, the computer executable instructions facilitating performing the steps of: obtaining, from a device definition database, a first device template corresponding to a device type, wherein the first device template includes a first definition of an editor interface for the device type; modifying the first definition of the editor interface via a customization tool associated with the editor interface for the device type, thereby rendering a modified version of the first definition of the editor interface; wherein the modifying step comprises customizing a download operation for commissioning device instances; and storing the modified version.
 9. The computer readable medium of claim 8 wherein the storing step comprises storing the modified version as a child template of the first device template.
 10. The computer-readable medium of claim 8 wherein the customization tool is invoked via a control exposed by the editor interface for the device type.
 11. A workstation including a computer-readable medium comprising computer-executable instructions for providing a software tool for use in a device configuration environment including the workstation for creating customized definitions for user interfaces provided by a field device editor, the tool comprising: an editor definition selection control for specifying a first device template corresponding to a device type stored in a device definition database, wherein the first device template includes a first definition of an editor interface for the device type; an editor graphical user interface, comprising a set of user-selectable screens for modifying the first definition of the editor interface via a customization tool associated with the editor interface for the device type, thereby rendering a modified version of the first definition of the editor interface; wherein the set of user-selectable screens comprises a user interface for customizing a download operation for commissioning device instances; and an editor store control for storing the modified version.
 12. The workstation of claim 11 wherein the set of user-selectable screens comprises a user interface for specifying groupings of parameters for use in the editor interface.
 13. The workstation of claim 11 wherein the set of user-selectable screens comprises a user interface for defining new screens to a set of interface screens associated with the field device editor.
 14. The workstation of claim 13 wherein the set of interface screens, including new screens, are accessed via tab controls on the field device editor graphical user interface.
 15. The workstation of claim 11 wherein the set of interface screens comprises a user interface for customizing permissions associated with particular user classes.
 16. The workstation of claim 11 wherein the modified version is storable as a child template of the first device template.
 17. The workstation of claim 11 wherein the customization tool is invoked via a control exposed by the editor interface for the device type. 